CN110253283B - Planet carrier part partial shipment device - Google Patents

Abstract

The invention discloses a planet carrier part subpackaging device, which is used for assembling parts in a planet carrier on a planet hub and comprises a positioning module and an installation module, wherein the positioning module comprises: the base is provided with a rotary disk for placing the planet hub; the center pin can be arranged in the middle of the base in a vertically moving mode and is used for initially positioning the part; and the knock pin can be arranged in the base in a vertically moving mode and is used for positioning the secondary positioning of the planet hub and the part at the mounting position, and the mounting module comprises: the clamping jaws can vertically move up and down and horizontally move back and forth and are used for picking and placing parts; the limiting assembly is used for limiting the moving stroke of the clamping jaw; when the part is installed, the part is initially positioned by the center pin, and then the part is horizontally pushed to the installation position of the part through the clamping jaws. The invention can realize simple and rapid assembly of planet carrier parts and can avoid the collision of workers in the assembly process.

Description

Planet carrier part partial shipment device

Technical Field

The invention relates to the technical field of gearbox assembly, in particular to a planet carrier part subpackaging device.

Background

The planet carrier in the gearbox is compact in structure, numerous in parts and small in internal space, so that the assembly space of a series of small parts such as planet pins, gaskets, bushings, planet gears and the like in the planet carrier is small, the assembly operability is low, and the assembly difficulty is large.

At present, in the assembling process of gearbox planet carrier parts, a series of small parts such as planet pins, gaskets, bushings and planet gears are usually installed in a planet hub in a manual mode, but because the planet carrier is internally provided with a plurality of small parts and has small internal space, the problems of personnel collision, low assembling efficiency, long time consumption and the like can be frequently caused in the manual assembling process, and the influence on production beat, cost and staff can be caused.

In addition, in the manual assembly process, the planet gear, the gasket, the bushing and the planet pin hole on the planet hub cannot be centered, so that the position deviation exists, and the difficulty is increased for installing the planet pin.

Disclosure of Invention

The invention aims to provide a planet carrier part subpackaging device, which is used for simply and quickly assembling parts in a planet carrier.

Therefore, the invention adopts the following technical scheme:

a split charging device for planet carrier parts, which is used for assembling parts in a planet carrier to a planet hub, wherein the parts comprise a planet gasket, a planet bushing and a planet gear, the split charging device comprises a positioning module for placing the planet hub and a mounting module for mounting the parts, and the positioning module comprises: a base having a rotating disk disposed thereon, wherein the planetary hub rests on the rotating disk; the central pin is arranged in the middle of the base in a vertically movable mode and provided with a working position extending upwards into the planetary hub, and when the central pin is located at the working position, the central pin is used for sleeving the part on the top of the central pin so as to realize initial positioning of the part; and a knock pin for positioning the planetary hub and the secondary positioning of the part at the mounting position, disposed in the base so as to be movable up and down, having a working position projecting upward into a planetary pin hole of the planetary hub, the mounting module including: the fixing base is provided with a vertical moving assembly and a horizontal moving assembly arranged on the vertical moving assembly, the horizontal moving assembly is connected with a clamping jaw used for taking and placing the part, the part is initially positioned by the center pin during installation, and then the clamping jaw horizontally pushes the part to an installation position of the part.

Further, the installation module further comprises a counterweight component for enabling the vertical moving component to be in a balanced state, so that manual light operation is realized.

Further, the counterweight assembly comprises a support fixedly arranged at the top of the fixed seat, a chain wheel arranged on the support, a counterweight block and a chain connected with the counterweight block and the vertical moving assembly.

Furthermore, the clamping jaws are vertically arranged and provided with extending ends extending forwards, U-shaped clamping grooves with forward openings are formed in the extending ends, and when the parts are conveyed, the parts are clamped in the U-shaped clamping grooves.

Further, the installation module still includes spacing subassembly, spacing subassembly is including being used for the restriction the first locating part of jack catch down position and being used for the restriction the second locating part of jack catch position of advancing, wherein, the jack catch is in when down position taking and putting the position height of part, the jack catch is in after being in down position when moving to the position of advancing the installation position of part.

Furthermore, an expansion spring is arranged at the bottom of the ejector pin, a second handle extending out of the base is connected to the ejector pin, a channel for the second handle to move up and down is formed in the base, and the expansion spring is in a normal state when the ejector pin is located at the working position.

Further, the bottom of the base is provided with an air cylinder for driving the center pin to move up and down.

Further, the knock pin overcoat is equipped with first oilless bush, the lower part cover of core pin is equipped with second oilless bush, the upper portion cover of core pin is equipped with the position sleeve.

Furthermore, a mandrel is arranged at the center of the top of the base, a thrust ball bearing is arranged outside the mandrel, and the rotary disc is rotatably connected to the base through the thrust ball bearing.

Furthermore, a rotating handle is arranged on the rotating disc.

The invention has the following technical effects:

(1) by using the split charging device, the assembly of the planet carrier parts can be simply and quickly carried out, the assembly efficiency is improved, the collision of workers in the assembly process can be avoided, in addition, the position precision among the planet gear, the planet gasket and the planet bush can be ensured, and the installation of the planet pin is facilitated;

(2) the invention can install the planet gear, the planet gasket and the planet bush at one time without manual back-and-forth split charging, thereby further ensuring the assembly efficiency and the installation effect;

(3) the split charging principle of the invention is simple and practical, has high popularization value, and can be applied to split charging of planet carrier parts of different planet carriers.

In addition to the objects, features and advantages described above, other objects, features and advantages of the present invention are also provided. The present invention will be described in further detail below with reference to the drawings.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this application, illustrate embodiments of the invention and, together with the description, serve to explain the invention and not to limit the invention. In the drawings:

FIG. 1 is a schematic structural diagram of a planetary carrier part split charging apparatus according to an embodiment of the present invention;

FIG. 2 illustrates a front view of a carrier type parts racking device according to one embodiment of the present invention;

FIG. 3 is a cross-sectional view taken along line A-A of FIG. 2;

FIG. 4 shows an internal structure of a positioning module in the planetary carrier type parts racking device according to an embodiment of the present invention;

FIG. 5 is a schematic view of the planet gear, the planet spacer, and the planet bushing in their initial positions;

FIG. 6 is a schematic view of the planet gear, the planet spacer, and the planet bushing in an installed position; and

fig. 7 shows the state after three sets of planet gears, planet spacers, and planet bushes are mounted on the planet hub.

Description of the reference numerals

1. A positioning module; 11. A base;

12. a rotary disk; 13. A center pin;

14. a knock pin; 15. A second handle;

16. a channel; 17. A cylinder;

18. a first oilless bushing; 19. A second oilless bushing;

2. installing a module; 21. A fixed seat;

22. a vertical movement assembly; 221. A first guide rail;

222. a first slider; 23. A horizontal movement assembly;

231. a second guide rail; 232. A second slider;

24. a claw; 241. A U-shaped clamping groove;

25. a first limit piece; 26. A second limiting member;

27. a sliding table; 28. A connecting plate;

29. a first handle; 30. A counterweight assembly;

301. a support; 302. A sprocket;

303. a balancing weight; 304. A chain;

31. a third limiting member; 32. A fourth limiting member;

33. a positioning sleeve; 34. A mandrel;

35. a thrust ball bearing; 36. Turning a handle;

37. a horizontal stopper plate; 38. A vertical stopper plate;

39. a bayonet; 100. And a planetary hub.

Detailed Description

It should be noted that the embodiments and features of the embodiments in the present application may be combined with each other without conflict. The present invention will be described in detail below with reference to the embodiments with reference to the attached drawings.

As shown in fig. 1 to 7, the carrier type parts racking device of the present invention is used for assembling parts in a carrier, including a planetary spacer, a planetary bushing, and a planetary gear, to a planetary hub 100, and includes a positioning module 1 for placing the planetary hub 100 and a mounting module 2 for mounting the parts.

As shown in fig. 1 to 7, the positioning module 1 includes a base 11, a rotary disk 12, a center pin 13, and a top pin 14.

The turntable 12 is rotatably disposed on top of the base 11, and the planetary hub 100 is placed on the turntable 12 when assembled.

The center pin 13 is disposed in the middle of the base 11 in a vertically movable manner, the center pin 13 has an operating position extending upward into the planetary hub 100 and an initial position retracted downward into the base 11, wherein the center pin 13 can fit the components (planetary spacers, planetary bushings, planetary gears) on top of the center pin 13 when in the operating position, so as to achieve the initial positioning of the components.

The knock pin 14 is provided in the base 11 to be movable up and down, the knock pin 14 has an operating position protruding upward into the planetary pin hole of the planetary hub 100 and a retracted position retracted downward into the base 11, the knock pin 14 can be used to position the planetary hub 100 when in the operating position, and the component is mounted to the planetary hub 100 at a position corresponding to the planetary pin hole, and the mounting position of the component when the knock pin 14 is in the retracted position is located directly above the knock pin 14, so that the knock pin 14 can be used to perform secondary positioning of the component when in the operating position.

As shown in fig. 1 to 3, the mounting module 2 includes a fixing base 21, a claw 24 for picking and placing the part, and a limiting component.

The fixed seat 21 is provided with a vertical moving assembly 22 and a horizontal moving assembly 23 which are fixedly connected with each other, the jaw 24 is connected to the horizontal moving assembly 23, wherein the jaw 24 can move back and forth along the horizontal direction through the horizontal moving assembly 23, and the horizontal moving assembly 23 can move up and down vertically through the vertical moving assembly 22.

The limiting assembly comprises a first limiting piece 25 used for limiting the descending position of the claw 24 and a second limiting piece 26 used for limiting the forward advancing position of the claw 24, wherein the height of the part at the initial positioning position is consistent with that of the installation position, the claw 24 is at the height for taking and placing the part when descending to the lowest position, and the claw 24 can push the part to the installation position of the part when advancing forward to the final position at the lowest height.

When the part is installed, the part is initially positioned by the central pin 13, then the part after initial positioning is clamped and taken by the clamping jaw 24, and then the part is horizontally pushed forward to the installation position of the part.

And a workbench is arranged below the fixed seat 21 and the base 11, and the fixed seat and the base are connected together through the workbench.

Specifically, as shown in fig. 1 to 3, the claw 24 is vertically arranged and has a protruding end protruding forward, and a U-shaped catch 241 with a forward opening is provided in the protruding end, and when the part is transported, the part is caught in the U-shaped catch 241. The extending ends of the claws 24 can extend into the inside of the hub 100 to facilitate the transportation of parts to an installation position, and the U-shaped slots 241 not only can achieve the purpose of picking and placing parts, but also can successfully reserve the insertion positions of the center pin 13 and the top pin 14.

Specifically, as shown in fig. 1 to 3, the vertical moving assembly 22 includes a first guide rail 221 fixedly connected to the fixing base 21 and a first sliding block 222 slidably connected to the first guide rail 221, the horizontal moving assembly 23 includes a second guide rail 231 and a second sliding block 232, two vertical moving assemblies 22 are arranged in parallel, the second guide rail 231 is fixedly connected to the first sliding blocks 222 of the two vertical moving assemblies 22 through a sliding table 27 with an L-shaped cross section, the claw 24 is fixedly connected to the second sliding block 232 through a connecting plate 28, and a first handle 29 convenient for the claw 24 to move is arranged on the connecting plate 28.

The vertical moving assembly 22 and the horizontal moving assembly 23 both adopt a sliding connection mode of a sliding block and a guide rail to enable the clamping jaw 24 to move, and the device has the characteristics of simple structure and convenience in operation.

As shown in fig. 1 to 3, the installation module 2 further includes a counterweight assembly 30, wherein the counterweight assembly 30 includes a support 301 fixedly disposed on the top of the fixing base 21, two sprockets 302 mounted on the support 301, a counterweight 303 playing a balancing role, and a chain 304 disposed on the two sprockets 302, and two ends of the chain 304 are respectively connected to the counterweight 303 and the sliding table 27.

The arrangement of the counterweight assembly 30 enables the vertical moving assembly 22 to be in a balanced state, so that labor can be saved when the clamping jaw 24 moves up and down, the operability of the clamping jaw 24 is greatly enhanced, and manual light operation can be realized.

As shown in fig. 1 to 3, the limiting assembly further includes a third limiting member 31 for limiting the upward travel position of the jaw 24 and a fourth limiting member 32 for limiting the backward travel position of the jaw 24.

First locating part 25, second locating part 26, third locating part 31 and fourth locating part 32 are the backstop round pin, spacing subassembly is still including linking firmly horizontal backstop board 37 on the slip table 27 and linking firmly vertical backstop board 38 on the fixing base 21, third locating part 31 and first locating part 25 set up respectively vertical backstop board 38's upper and lower both ends, second locating part 26 and fourth locating part 32 set up respectively horizontal backstop board 37's front and back both ends.

The vertical stop plate 38, the third limiting member 31 and the first limiting member 25 can limit the up-down stroke of the first slider 222, and the horizontal stop plate 37, the second limiting member 26 and the fourth limiting member 32 can limit the back-and-forth movement stroke of the second slider 232. The limiting assembly is simple in structure, easy to process and low in manufacturing cost.

Specifically, as shown in fig. 1 to 7, a second handle 15 extending out of the base 11 is connected to the knock pin 14 through a screw thread, a channel 16 for the second handle 15 to move up and down is formed in the base 11, a telescopic spring is arranged at the bottom of the knock pin 14, and a worker can drive the knock pin 14 to move by moving the second handle 15. When the knock pin 14 is in the working position, that is, when the knock pin 14 extends into the planetary pin hole of the hub 100, the extension spring is in a normal state, and when the knock pin 14 is retracted into the base 11, the extension spring is in a compressed state.

The up-and-down movement of the ejector pin 14 is operated in a manual mode, the impact force is small, and the installation precision is guaranteed.

The lower part of the channel 16 is provided with a bayonet 39 used for clamping the second handle 15, and when the second handle 15 is clamped into the bayonet 39, the ejector pin 14 can be fixed at a contraction position, so that the ejector pin 14 is prevented from being upwards bounced by the telescopic spring.

In one embodiment, as shown in fig. 2 to 4, an air cylinder 17 for driving the center pin 13 to move up and down is disposed at the bottom of the base 11, and a connection joint is disposed between a piston rod of the air cylinder 17 and the center pin 13.

As shown in fig. 3 and 4, the knock pin 14 is sleeved with a first oilless bushing 18, the lower portion of the center pin 13 is sleeved with two second oilless bushings 19, a spacer is arranged between the two second oilless bushings 19, and the upper portion of the center pin 13 is sleeved with a positioning sleeve 33 for positioning the center pin 13. The second oilless bushing 19 is in clearance fit with the center pin 13, and the second oilless bushing 19 is in interference fit with the base 11.

As shown in fig. 3 and 4, a mandrel 34 is fixedly connected to the top center of the base 11 through a bolt, a thrust ball bearing 35 is arranged outside the mandrel 34, and the rotary disk 12 is rotatably connected to the base 11 through the thrust ball bearing 35.

A deep groove ball bearing is further arranged between the mandrel 34 and the positioning sleeve 33.

In one embodiment, as shown in fig. 1, a rotating handle 36 is fixed to a side of the rotating disc 12 for facilitating the rotation of the rotating disc 12.

The invention is further described in detail below with reference to specific working procedures:

firstly, manually placing a planetary hub 100 on the rotary disk 12, and positioning the planetary hub 100 by inserting the knock pins 14 into the planetary pin holes of the planetary hub 100;

then, the air cylinder 17 drives the central pin 13 to move upwards to reach the working position of the central pin 13, and a planetary gasket, a planetary bushing and a planetary gear sleeve are manually arranged at the top of the central pin 13 so as to realize the initial positioning of the planetary gasket, the planetary bushing and the planetary gear;

then the staff holds the first handle 29 to move the claw 24 to the lowest position, then moves forwards until the planet gasket, the planet bushing and the planet tooth enter the U-shaped clamping groove 241 of the claw 24, the center pin 13 retracts downwards, the staff continues to move the claw 24 forwards, and the knock pin 14 moves downwards when the planet gasket, the planet bushing and the planet gear reach the installation position;

then, the clamping jaws 24 are continuously moved forwards until the part installation position is reached, the ejector pin 14 is moved upwards and inserted into the planet pin hole, at the moment, the planet gasket, the planet bushing and the planet tooth can be centered with the planet pin hole through the ejector pin 14, and finally, the planet pin is installed into the planet pin hole, so that the part installation at one planet pin hole on the planet carrier can be completed.

In this embodiment, the planetary hub 100 has three planetary pin holes for mounting components, and the rotating disk 12 is rotated by 120 degrees so that another planetary pin hole on the planetary hub 100 is rotated to be inserted by the knock pin 14, and then the above operations are repeated, so that the mounting of the components at the another planetary pin hole on the planetary carrier can be completed. Similarly, the installation of the part at the third planet pin hole can be completed according to the operation process.

By using the split charging device, the assembly of the planet carrier parts can be simply and quickly carried out, the assembly efficiency is improved, the collision of workers in the assembly process can be avoided, in addition, the position precision among the planet gear, the planet gasket and the planet bush can be ensured, and the installation of the planet pin is facilitated.

The invention can install the planet gear, the planet gasket and the planet bushing at one time without manual back-and-forth split charging, thereby further ensuring the assembly efficiency and the installation effect.

The split charging principle of the invention is simple and practical, has high popularization value, and can be applied to split charging of planet carrier parts of different planet carriers.

In addition, it should be noted that the mode of the cylinder driving the center pin to move in the present invention can be replaced by manual movement, for example, the mode of the cylinder driving the center pin to move in the present invention is a manual movement, and the mode of the cylinder driving the center pin to move in the present invention is replaced by manual rotation, and the mode of the manual rotation of the rotary disk is replaced by automatic rotation, for example, the mode of the cylinder driving the center pin to rotate by servo or rotation of the cylinder is a conventional replacement in mechanical design, and both the mode and the method belong to the protection scope.

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. A split charging device for planet carrier type parts, for assembling the parts in a planet carrier to a planet hub (100), said parts comprising planet spacers, planet bushings and planet gears, characterized in that the split charging device comprises a positioning module (1) for placing the planet hub (100) and a mounting module (2) for mounting the parts, wherein

The positioning module (1) comprises:

a base (11) on which a rotating disc (12) is provided, wherein the planetary hub (100) is placed on the rotating disc (12);

the central pin (13) is arranged in the middle of the base (11) in a vertically movable mode and has a working position extending upwards into the planetary hub (100), and when the central pin (13) is in the working position, the part is sleeved on the top of the central pin (13) so as to realize initial positioning of the part; and

a knock pin (14) for positioning the planetary hub (100) and the secondary positioning of the component at the mounting position, disposed in the base (11) so as to be movable up and down, having a working position projecting up into a planetary pin hole of the planetary hub (100);

the installation module (2) comprises:

a fixed seat (21) which is provided with a vertical moving component (22) and a horizontal moving component (23) arranged on the vertical moving component (22), the horizontal moving component (23) is connected with a claw (24) used for taking and placing the part,

when the part is installed, the part is initially positioned by the central pin (13), and then the part is horizontally pushed to an installation position of the part by the clamping jaws (24);

the part is arranged on the planet hub (100) at a position corresponding to the planet pin hole, and the installation position of the part is positioned right above the knock pin (14) when the knock pin (14) is in the contraction position, so that the knock pin (14) can be used for secondary positioning of the part at the installation position when the knock pin (14) is in the working position.

2. A planet carrier parts racking device as claimed in claim 1, wherein said mounting module (2) further comprises a counterweight assembly (30) for balancing said vertical moving assembly (22) for manual ease of operation.

3. A planet carrier parts racking device according to claim 2 wherein said counterweight assembly (30) comprises a support (301) secured to the top of said fixed base (21), a sprocket (302) mounted on said support (301), a counterweight (303), and a chain (304) connecting said counterweight (303) to said vertically moving assembly (22).

4. A carrier type part dispensing apparatus according to claim 1, wherein the claw (24) is vertically disposed and has a forwardly projecting end in which a forwardly opening U-shaped catch (241) is provided, the part being caught in the U-shaped catch (241) when the part is transported.

5. A planet carrier part dispensing apparatus according to claim 4, wherein the mounting module (2) further comprises a limiting assembly, the limiting assembly comprises a first limiting member (25) for limiting the descending position of the claw (24) and a second limiting member (26) for limiting the advancing position of the claw (24), wherein the claw (24) is at the position height for taking and placing the part when in the descending position, and the claw (24) is at the mounting position of the part when moving to the advancing position after being in the descending position.

6. A carrier part dispensing apparatus according to claim 1, characterised in that the top pin (14) is provided with a telescopic spring at its bottom, the top pin (14) is connected to a second handle (15) extending out of the base (11), the base (11) is provided with a passage (16) for the second handle (15) to move up and down, wherein the telescopic spring is in a normal state when the top pin (14) is in the operating position.

7. A planet carrier type part dispensing apparatus according to claim 1, wherein the base (11) is provided at its bottom with a cylinder (17) for driving the center pin (13) up and down.

8. A carrier type part dispensing apparatus according to claim 1, wherein the knock pin (14) is externally fitted with a first oilless bush (18), the center pin (13) is externally fitted with a second oilless bush (19) at a lower portion thereof, and the center pin (13) is externally fitted with a positioning bush (33) at an upper portion thereof.

9. A planet carrier type part subpackaging device according to claim 1, wherein a mandrel (34) is arranged at the top center of the base (11), a thrust ball bearing (35) is arranged outside the mandrel (34), and the rotary disk (12) is rotatably connected on the base (11) through the thrust ball bearing (35).

10. A planet carrier type part dispensing apparatus according to claim 1, wherein the rotary disc (12) is provided with a rotary handle (36).

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